Heat shock protein Gp96-Ig-peptide complexes based vaccine induce predominant immune responses at mucosal sites (46.13)

Abstract We have developed a vaccine design that uses the unique ability of the endoplasmic reticulum (ER) chaperone, heat shock protein gp96, to bind antigenic peptides and deliver them to antigen-presenting cells. Secreted form of gp96, gp96-Ig, was generated by replacing the ER retention sequence KDEL with the IgG1-Fc domain. To generate a cellular SIV vaccine, HEK-293 cells were transfected with gp96-Ig and the cDNAs encoding the SIV antigens gag, env and retanef. Irradiated, transfected 293 cells that secrete 1, 5 or 50 micrograms gp96-Ig-SIV complexes in 24h, were injected intraperitoneally (IP) in Mamu-A*01+ Rhesus Macaques at 0, 4 and 25 weeks. To determine whether gp96-Ig vaccination induces mucosal immunity, we used the 3T3-OVA-gp96-Ig/OT-1 model. Our data indicate that the best route of vaccination for induction of mucosal CD8-CTL immunity is the IP route. Gp96-Ig immunization increases frequency of CD11chighMHC classIIhighCD103+ cells in peritoneal cavity and efficiently induces CCR9 on responding T cells. In nonhuman primate model, the frequency of SIV-specific cells in the rectal mucosa reached 30-50% after the third immunization. We conclude that gp96-Ig vaccination startegy induces antigen-specific effector memory CD8T cells migrating to the intestinal mucosa and thus could be extremely useful for improving protection against a range of mucosal pathogens

Interleukin-21 administration to rhesus macaques chronically infected with simian immunodeficiency virus increases cytotoxic effector molecules in T cells and NK cells and enhances B cell function without increasing immune activation or viral replication

► IL-21 administration to chronically SIV infected RM was safe and biologically active. ► IL-21administration increases cytotoxic effector molecules perforin and granzyme B in T cells and NK cells. ► IL-21 treatment increases memory B cell pool and anti-SIV Ab levels. ► IL-21 administration did not alter immune activation or plasma SIV RNA levels. We have previously shown that interleukin-21, a pleiotropic C γ-chain signaling cytokine, induces the expression of the cytotoxic molecules granzyme B (GrB) and perforin in vitro in CD8 T cells and NK cells of chronically HIV infected individuals. In this pilot study, four chronically SIV infected rhesus macaques (RM) in late-stage disease were given two doses of recombinant MamuIL-21, 50μg/kg, intravenously 7 days apart, followed by one subcutaneous dose, 100μg/kg, 23 days after the second dose. Three animals served as controls. After each dose of IL-21, increases were noted in frequency and mean fluorescence intensity of GrB and perforin expression in memory and effector subsets of CD8 T cells in peripheral blood (PB), in peripheral and mesenteric lymph node (LN) cells, in PB memory and effector CD4 T cells and in NK cells. Frequencies of SIV-gag specific CD107a+IFN-γ+ CD8 T cells increased 3.8-fold in PB and 1.8-fold in LN. In addition, PB CD27+ memory B cells were 2-fold higher and serum SIV antibodies increased significantly after IL-21 administration. No changes were observed in markers of T cell activation, T cell proliferation or plasma virus load. Thus, administration of IL-21 to chronically SIV infected viremic animals was safe, well tolerated and could augment the cytotoxic potential of T cells and NK cells, promote B cell differentiation with increases in SIV antibody titers without discernable increase in cellular activation. Further studies are warranted to elucidate the effects and potential benefit of IL-21 administration in the context of SIV/HIV infection and in SIV/HIV vaccine design

Powerful mucosal immune response in macaques (Macaca mulatta) in response to SIV gp96-Ig immunization (39.35)

Abstract Induction of mucosal immunity is critical for protection from enteric pathogens. We have developed a vaccine design that utilizes the unique property of the endoplasmic reticulum chaperon, heat shock protein (HSP) gp96, to bind antigenic peptides and deliver them to APCs. The aim of our study was to evaluate safety and systemic and mucosal SIV-immunity with secreted gp96-Ig vaccines in non-human primates. We have generated a secreted form gp96 by replacing the ER retention sequence KDEL with the IgG1-Fc tag. HEK-293 cells were transfected with gp96-Ig and with the cDNAs encoding the SIV antigens gag, pol, env and retanef (reassorted rev, tat, nef). Irradiated, transfected 293 cells that secrete 1, 5 or 50 micrograms gp96-Ig-SIV-peptide complexes in 24h, were injected intraperitoneally in Mamu-A*01+ macaques at 0, 4 and 24 weeks. The frequency of SIVGag- and SIVTat- tetramer+ cells in the rectal mucosa reached 30-50% in some macaques after the third immunization. Tetramer+ cells expressed appropriate functional (granzymeB) and migration markers (alpha4beta7, CD103). The cells secrete IL-2 and IFN-gamma in response to different peptide (gag, tat, env) stimulation. We conclude that the cell secreted SIV-gp96-Ig vaccine is safe and can induce strong poly-specific, multifunctional CD8 responses in mucosal compartments that are thought to be critical for protection from SIV/HIV infection

Cutting Edge: Novel Vaccination Modality Provides Significant Protection against Mucosal Infection by Highly Pathogenic Simian Immunodeficiency Virus

Vaccine induced protection against infection by HIV or highly pathogenic and virulent SIV-strains has been limited. Here, in a proof of concept study, we show that a novel vaccine approach significantly protects Rhesus macaques from mucosal infection by the highly pathogenic strain SIV(mac251). We vaccinated 3 cohorts of 12 macaques each with live, irradiated vaccine cells secreting the modified ER chaperone gp96(−)Ig. Cohort 1 was vaccinated with cells secreting gp96(SIV)Ig carrying SIV peptides. Cohort 2 in addition received recombinant envelope protein SIV-gp120. Cohort 3 was injected with cells secreting gp96-Ig (no SIV antigens) vaccines. Cohort 2 was protected from infection. After seven rectal challenges with highly pathogenic SIV(mac251) the hazard ratio was 0.27 corresponding to a highly significant, 73% reduced risk of viral acquisition. The apparent success of the novel vaccine modality recommends further study

Gp96SIVIg immunization induces potent polyepitope specific, multifunctional memory responses in rectal and vaginal mucosa

The ER-resident chaperone gp96, when released by cell lysis, induces an immunogenic chemokine signature and causes innate immune activation of DC and NK cells. Here we show that intraperitoneal immunization with a genetically engineered, secreted form of gp96, gp96-Ig chaperoning SIV antigens, induces high levels of antigen specific CD8 CTL in the rectal and vaginal mucosa of Rhesus macaques. The frequency of SIV Gag- and SIV Tat-tetramer positive CD8 CTL in the intestinal mucosa reached 30-50% after the third immunization. Tetramer positive CD8 CTL expressed appropriate functional (granzyme B) and migration markers (CD103). The polyepitope specificity of the mucosal CD8 and CD4 response is evident from a strong, multifunctional cytokine response upon stimulation with peptides covering the gag, tat and env proteins. Induction of powerful mucosal effector CD8 CTL responses by cell-based gp96(SIV)-Ig immunization may provide a pathway to the development of safe and effective SIV/HIV vaccines

Interleukin-21 administration to rhesus macaques chronically infected with simian immunodeficiency virus increases cytotoxic effector molecules in T cells and NK cells and enhances B cell function without increasing immune activation or viral replication

We have previously shown that Interleukin-21, a pleiotropic C γ-chain signaling cytokine, induces the expression of the cytotoxic molecules granzyme B (GrB) and perforin in vitro in CD8 T cells and NK cells of chronically HIV infected individuals. In this pilot study, four chronically SIV infected Rhesus macaques (RM) in late- stage disease were given two doses of recombinant MamuIL-21, 50μg/kg, intravenously 7 days apart, followed by one subcutaneous dose, 100μg/kg, 23 days after the second dose. Three animals served as controls. After each dose of IL-21, increases were noted in frequency and mean fluorescence intensity of GrB and perforin expression in memory and effector subsets of CD8 T cells in peripheral blood (PB), in peripheral and mesenteric lymph node (LN) cells, in PB memory and effector CD4 T cells and in NK cells. Frequencies of SIV-gag specific CD107a(+)IFNγ(+) CD8 increased 3.8 fold in PB and 1.8 fold in LN. In addition, PB CD27(+) memory B cells were 2 fold higher and serum SIV antibodies increased significantly after IL-21 administration. No changes were observed in markers of T cell activation, T cell proliferation or plasma virus load. Thus, administration of IL-21 to chronically SIV infected viremic animals was safe, well tolerated and could augment the cytotoxic potential of T cells and NK cells, promote B cell differentiation with increases in SIV antibody titers without discernable increase in cellular activation. Further studies are warranted to elucidate the effects and potential benefit of IL-21 administration in the context of SIV/HIV infection and in HIV/SIV vaccine design

Erratum to: Guidelines for the use and interpretation of assays for monitoring autophagy (3rd edition) (Autophagy, 12, 1, 1-222, 10.1080/15548627.2015.1100356

non present